Spatial adiabatic passage of ultracold atoms in optical tweezers

• URL: http://arxiv.org/abs/2305.16228v1
• Date: Thu, 25 May 2023 16:35:30 GMT
• Title: Spatial adiabatic passage of ultracold atoms in optical tweezers
• Authors: Yanay Florshaim, Elad Zohar, David Zeev Koplovich, Ilan Meltzer, Rafi Weill, Jonathan Nemirovsky, Amir Stern, Yoav Sagi
• Abstract summary: We report the implementation of SAP for transferring massive particles between three micro-optical traps. We observe a smooth transfer of atoms between the two outer traps, accompanied by a low population in the central trap. Our results open up new possibilities for advanced control and manipulation schemes in optical tweezer array platforms.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Spatial adiabatic passage (SAP) is a process that facilitates the transfer of a wave packet between two localized modes that are not directly coupled, but rather interact through an intermediate third mode. By employing a counter-intuitive adiabatic pulse sequence, this technique achieves minimal population in the intermediate state and high transfer efficiency. Here, we report the implementation of SAP for transferring massive particles between three micro-optical traps. We begin by preparing ultracold fermionic atoms in low vibrational eigenstates of one trap and then manipulate the distance between the three traps to execute the SAP protocol. We observe a smooth transfer of atoms between the two outer traps, accompanied by a low population in the central trap. We validate our findings and underscore the significance of the counter-intuitive sequence by reversing the order of the pulse sequence. Additionally, we investigate the influence of the tunneling rate and the time delay between the motion of the two external tweezers on the fidelity of the process. Our results open up new possibilities for advanced control and manipulation schemes in optical tweezer array platforms.

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